virtualx-engine/thirdparty/embree/kernels/geometry/curveNi_mb_intersector.h
Jakub Mateusz Marcowski c43eab55a4
embree: Update to 4.3.1
2024-03-27 22:10:35 +01:00

531 lines
25 KiB
C++

// Copyright 2009-2021 Intel Corporation
// SPDX-License-Identifier: Apache-2.0
#pragma once
#include "curveNi_mb.h"
#include "../subdiv/linear_bezier_patch.h"
#include "roundline_intersector.h"
#include "coneline_intersector.h"
#include "curve_intersector_ribbon.h"
#include "curve_intersector_oriented.h"
#include "curve_intersector_sweep.h"
namespace embree
{
namespace isa
{
template<int M>
struct CurveNiMBIntersector1
{
typedef CurveNiMB<M> Primitive;
typedef Vec3vf<M> Vec3vfM;
typedef LinearSpace3<Vec3vfM>LinearSpace3vfM;
typedef CurvePrecalculations1 Precalculations;
static __forceinline vbool<M> intersect(Ray& ray, const Primitive& prim, vfloat<M>& tNear_o)
{
const size_t N = prim.N;
#if __SYCL_DEVICE_ONLY__
const Vec3f offset = *prim.offset(N);
const float scale = *prim.scale(N);
#else
const vfloat4 offset_scale = vfloat4::loadu(prim.offset(N));
const Vec3fa offset = Vec3fa(offset_scale);
const Vec3fa scale = Vec3fa(shuffle<3,3,3,3>(offset_scale));
#endif
const Vec3fa org1 = (ray.org-offset)*scale;
const Vec3fa dir1 = ray.dir*scale;
const LinearSpace3vfM space(vfloat<M>::load(prim.bounds_vx_x(N)), vfloat<M>::load(prim.bounds_vx_y(N)), vfloat<M>::load(prim.bounds_vx_z(N)),
vfloat<M>::load(prim.bounds_vy_x(N)), vfloat<M>::load(prim.bounds_vy_y(N)), vfloat<M>::load(prim.bounds_vy_z(N)),
vfloat<M>::load(prim.bounds_vz_x(N)), vfloat<M>::load(prim.bounds_vz_y(N)), vfloat<M>::load(prim.bounds_vz_z(N)));
const Vec3vfM dir2 = xfmVector(space,Vec3vfM(dir1));
const Vec3vfM org2 = xfmPoint (space,Vec3vfM(org1));
const Vec3vfM rcp_dir2 = rcp_safe(dir2);
const vfloat<M> ltime = (ray.time()-prim.time_offset(N))*prim.time_scale(N);
const vfloat<M> vx_lower0 = vfloat<M>::load(prim.bounds_vx_lower0(N));
const vfloat<M> vx_lower1 = vfloat<M>::load(prim.bounds_vx_lower1(N));
const vfloat<M> vx_lower = madd(ltime,vx_lower1-vx_lower0,vx_lower0);
const vfloat<M> vx_upper0 = vfloat<M>::load(prim.bounds_vx_upper0(N));
const vfloat<M> vx_upper1 = vfloat<M>::load(prim.bounds_vx_upper1(N));
const vfloat<M> vx_upper = madd(ltime,vx_upper1-vx_upper0,vx_upper0);
const vfloat<M> vy_lower0 = vfloat<M>::load(prim.bounds_vy_lower0(N));
const vfloat<M> vy_lower1 = vfloat<M>::load(prim.bounds_vy_lower1(N));
const vfloat<M> vy_lower = madd(ltime,vy_lower1-vy_lower0,vy_lower0);
const vfloat<M> vy_upper0 = vfloat<M>::load(prim.bounds_vy_upper0(N));
const vfloat<M> vy_upper1 = vfloat<M>::load(prim.bounds_vy_upper1(N));
const vfloat<M> vy_upper = madd(ltime,vy_upper1-vy_upper0,vy_upper0);
const vfloat<M> vz_lower0 = vfloat<M>::load(prim.bounds_vz_lower0(N));
const vfloat<M> vz_lower1 = vfloat<M>::load(prim.bounds_vz_lower1(N));
const vfloat<M> vz_lower = madd(ltime,vz_lower1-vz_lower0,vz_lower0);
const vfloat<M> vz_upper0 = vfloat<M>::load(prim.bounds_vz_upper0(N));
const vfloat<M> vz_upper1 = vfloat<M>::load(prim.bounds_vz_upper1(N));
const vfloat<M> vz_upper = madd(ltime,vz_upper1-vz_upper0,vz_upper0);
const vfloat<M> t_lower_x = (vx_lower-vfloat<M>(org2.x))*vfloat<M>(rcp_dir2.x);
const vfloat<M> t_upper_x = (vx_upper-vfloat<M>(org2.x))*vfloat<M>(rcp_dir2.x);
const vfloat<M> t_lower_y = (vy_lower-vfloat<M>(org2.y))*vfloat<M>(rcp_dir2.y);
const vfloat<M> t_upper_y = (vy_upper-vfloat<M>(org2.y))*vfloat<M>(rcp_dir2.y);
const vfloat<M> t_lower_z = (vz_lower-vfloat<M>(org2.z))*vfloat<M>(rcp_dir2.z);
const vfloat<M> t_upper_z = (vz_upper-vfloat<M>(org2.z))*vfloat<M>(rcp_dir2.z);
const vfloat<M> round_up (1.0f+3.0f*float(ulp));
const vfloat<M> round_down(1.0f-3.0f*float(ulp));
const vfloat<M> tNear = round_down*max(mini(t_lower_x,t_upper_x),mini(t_lower_y,t_upper_y),mini(t_lower_z,t_upper_z),vfloat<M>(ray.tnear()));
const vfloat<M> tFar = round_up *min(maxi(t_lower_x,t_upper_x),maxi(t_lower_y,t_upper_y),maxi(t_lower_z,t_upper_z),vfloat<M>(ray.tfar));
tNear_o = tNear;
return (vint<M>(step) < vint<M>(prim.N)) & (tNear <= tFar);
}
template<typename Intersector, typename Epilog>
static __forceinline void intersect_t(const Precalculations& pre, RayHit& ray, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(normal.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
Vec3ff a0,a1,a2,a3; geom->gather(a0,a1,a2,a3,geom->curve(primID),ray.time());
Intersector().intersect(pre,ray,context,geom,primID,a0,a1,a2,a3,Epilog(ray,context,geomID,primID));
mask &= movemask(tNear <= vfloat<M>(ray.tfar));
}
}
template<typename Intersector, typename Epilog>
static __forceinline bool occluded_t(const Precalculations& pre, Ray& ray, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(shadow.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
Vec3ff a0,a1,a2,a3; geom->gather(a0,a1,a2,a3,geom->curve(primID),ray.time());
if (Intersector().intersect(pre,ray,context,geom,primID,a0,a1,a2,a3,Epilog(ray,context,geomID,primID)))
return true;
mask &= movemask(tNear <= vfloat<M>(ray.tfar));
}
return false;
}
template<typename Intersector, typename Epilog>
static __forceinline void intersect_n(const Precalculations& pre, RayHit& ray, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(normal.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
const TensorLinearCubicBezierSurface3fa curve = geom->getNormalOrientedCurve<typename Intersector::SourceCurve3ff, typename Intersector::SourceCurve3fa, TensorLinearCubicBezierSurface3fa>(context, ray.org, primID,ray.time());
Intersector().intersect(pre,ray,context,geom,primID,curve,Epilog(ray,context,geomID,primID));
mask &= movemask(tNear <= vfloat<M>(ray.tfar));
}
}
template<typename Intersector, typename Epilog>
static __forceinline bool occluded_n(const Precalculations& pre, Ray& ray, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(shadow.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
const TensorLinearCubicBezierSurface3fa curve = geom->getNormalOrientedCurve<typename Intersector::SourceCurve3ff, typename Intersector::SourceCurve3fa, TensorLinearCubicBezierSurface3fa>(context, ray.org, primID,ray.time());
if (Intersector().intersect(pre,ray,context,geom,primID,curve,Epilog(ray,context,geomID,primID)))
return true;
mask &= movemask(tNear <= vfloat<M>(ray.tfar));
}
return false;
}
template<typename Intersector, typename Epilog>
static __forceinline void intersect_h(const Precalculations& pre, RayHit& ray, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(normal.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
Vec3ff p0,t0,p1,t1; geom->gather_hermite(p0,t0,p1,t1,geom->curve(primID),ray.time());
Intersector().intersect(pre,ray,context,geom,primID,p0,t0,p1,t1,Epilog(ray,context,geomID,primID));
mask &= movemask(tNear <= vfloat<M>(ray.tfar));
}
}
template<typename Intersector, typename Epilog>
static __forceinline bool occluded_h(const Precalculations& pre, Ray& ray, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(shadow.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
Vec3ff p0,t0,p1,t1; geom->gather_hermite(p0,t0,p1,t1,geom->curve(primID),ray.time());
if (Intersector().intersect(pre,ray,context,geom,primID,p0,t0,p1,t1,Epilog(ray,context,geomID,primID)))
return true;
mask &= movemask(tNear <= vfloat<M>(ray.tfar));
}
return false;
}
template<typename Intersector, typename Epilog>
static __forceinline void intersect_hn(const Precalculations& pre, RayHit& ray, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(normal.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
const TensorLinearCubicBezierSurface3fa curve = geom->getNormalOrientedHermiteCurve<typename Intersector::SourceCurve3ff, typename Intersector::SourceCurve3fa, TensorLinearCubicBezierSurface3fa>(context, ray.org, primID,ray.time());
Intersector().intersect(pre,ray,context,geom,primID,curve,Epilog(ray,context,geomID,primID));
mask &= movemask(tNear <= vfloat<M>(ray.tfar));
}
}
template<typename Intersector, typename Epilog>
static __forceinline bool occluded_hn(const Precalculations& pre, Ray& ray, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(shadow.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
const TensorLinearCubicBezierSurface3fa curve = geom->getNormalOrientedHermiteCurve<typename Intersector::SourceCurve3ff, typename Intersector::SourceCurve3fa, TensorLinearCubicBezierSurface3fa>(context, ray.org, primID,ray.time());
if (Intersector().intersect(pre,ray,context,geom,primID,curve,Epilog(ray,context,geomID,primID)))
return true;
mask &= movemask(tNear <= vfloat<M>(ray.tfar));
}
return false;
}
};
template<int M, int K>
struct CurveNiMBIntersectorK
{
typedef CurveNiMB<M> Primitive;
typedef Vec3vf<M> Vec3vfM;
typedef LinearSpace3<Vec3vfM>LinearSpace3vfM;
typedef CurvePrecalculationsK<K> Precalculations;
static __forceinline vbool<M> intersect(RayK<K>& ray, const size_t k, const Primitive& prim, vfloat<M>& tNear_o)
{
const size_t N = prim.N;
#if __SYCL_DEVICE_ONLY__
const Vec3f offset = *prim.offset(N);
const float scale = *prim.scale(N);
#else
const vfloat4 offset_scale = vfloat4::loadu(prim.offset(N));
const Vec3fa offset = Vec3fa(offset_scale);
const Vec3fa scale = Vec3fa(shuffle<3,3,3,3>(offset_scale));
#endif
const Vec3fa ray_org(ray.org.x[k],ray.org.y[k],ray.org.z[k]);
const Vec3fa ray_dir(ray.dir.x[k],ray.dir.y[k],ray.dir.z[k]);
const Vec3fa org1 = (ray_org-offset)*scale;
const Vec3fa dir1 = ray_dir*scale;
const LinearSpace3vfM space(vfloat<M>::load(prim.bounds_vx_x(N)), vfloat<M>::load(prim.bounds_vx_y(N)), vfloat<M>::load(prim.bounds_vx_z(N)),
vfloat<M>::load(prim.bounds_vy_x(N)), vfloat<M>::load(prim.bounds_vy_y(N)), vfloat<M>::load(prim.bounds_vy_z(N)),
vfloat<M>::load(prim.bounds_vz_x(N)), vfloat<M>::load(prim.bounds_vz_y(N)), vfloat<M>::load(prim.bounds_vz_z(N)));
const Vec3vfM dir2 = xfmVector(space,Vec3vfM(dir1));
const Vec3vfM org2 = xfmPoint (space,Vec3vfM(org1));
const Vec3vfM rcp_dir2 = rcp_safe(dir2);
const vfloat<M> ltime = (ray.time()[k]-prim.time_offset(N))*prim.time_scale(N);
const vfloat<M> vx_lower0 = vfloat<M>::load(prim.bounds_vx_lower0(N));
const vfloat<M> vx_lower1 = vfloat<M>::load(prim.bounds_vx_lower1(N));
const vfloat<M> vx_lower = madd(ltime,vx_lower1-vx_lower0,vx_lower0);
const vfloat<M> vx_upper0 = vfloat<M>::load(prim.bounds_vx_upper0(N));
const vfloat<M> vx_upper1 = vfloat<M>::load(prim.bounds_vx_upper1(N));
const vfloat<M> vx_upper = madd(ltime,vx_upper1-vx_upper0,vx_upper0);
const vfloat<M> vy_lower0 = vfloat<M>::load(prim.bounds_vy_lower0(N));
const vfloat<M> vy_lower1 = vfloat<M>::load(prim.bounds_vy_lower1(N));
const vfloat<M> vy_lower = madd(ltime,vy_lower1-vy_lower0,vy_lower0);
const vfloat<M> vy_upper0 = vfloat<M>::load(prim.bounds_vy_upper0(N));
const vfloat<M> vy_upper1 = vfloat<M>::load(prim.bounds_vy_upper1(N));
const vfloat<M> vy_upper = madd(ltime,vy_upper1-vy_upper0,vy_upper0);
const vfloat<M> vz_lower0 = vfloat<M>::load(prim.bounds_vz_lower0(N));
const vfloat<M> vz_lower1 = vfloat<M>::load(prim.bounds_vz_lower1(N));
const vfloat<M> vz_lower = madd(ltime,vz_lower1-vz_lower0,vz_lower0);
const vfloat<M> vz_upper0 = vfloat<M>::load(prim.bounds_vz_upper0(N));
const vfloat<M> vz_upper1 = vfloat<M>::load(prim.bounds_vz_upper1(N));
const vfloat<M> vz_upper = madd(ltime,vz_upper1-vz_upper0,vz_upper0);
const vfloat<M> t_lower_x = (vx_lower-vfloat<M>(org2.x))*vfloat<M>(rcp_dir2.x);
const vfloat<M> t_upper_x = (vx_upper-vfloat<M>(org2.x))*vfloat<M>(rcp_dir2.x);
const vfloat<M> t_lower_y = (vy_lower-vfloat<M>(org2.y))*vfloat<M>(rcp_dir2.y);
const vfloat<M> t_upper_y = (vy_upper-vfloat<M>(org2.y))*vfloat<M>(rcp_dir2.y);
const vfloat<M> t_lower_z = (vz_lower-vfloat<M>(org2.z))*vfloat<M>(rcp_dir2.z);
const vfloat<M> t_upper_z = (vz_upper-vfloat<M>(org2.z))*vfloat<M>(rcp_dir2.z);
const vfloat<M> round_up (1.0f+3.0f*float(ulp));
const vfloat<M> round_down(1.0f-3.0f*float(ulp));
const vfloat<M> tNear = round_down*max(mini(t_lower_x,t_upper_x),mini(t_lower_y,t_upper_y),mini(t_lower_z,t_upper_z),vfloat<M>(ray.tnear()[k]));
const vfloat<M> tFar = round_up *min(maxi(t_lower_x,t_upper_x),maxi(t_lower_y,t_upper_y),maxi(t_lower_z,t_upper_z),vfloat<M>(ray.tfar[k]));
tNear_o = tNear;
return (vint<M>(step) < vint<M>(prim.N)) & (tNear <= tFar);
}
template<typename Intersector, typename Epilog>
static __forceinline void intersect_t(Precalculations& pre, RayHitK<K>& ray, const size_t k, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,k,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(normal.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
Vec3ff a0,a1,a2,a3; geom->gather(a0,a1,a2,a3,geom->curve(primID),ray.time()[k]);
Intersector().intersect(pre,ray,k,context,geom,primID,a0,a1,a2,a3,Epilog(ray,k,context,geomID,primID));
mask &= movemask(tNear <= vfloat<M>(ray.tfar[k]));
}
}
template<typename Intersector, typename Epilog>
static __forceinline bool occluded_t(Precalculations& pre, RayK<K>& ray, const size_t k, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,k,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(shadow.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
Vec3ff a0,a1,a2,a3; geom->gather(a0,a1,a2,a3,geom->curve(primID),ray.time()[k]);
if (Intersector().intersect(pre,ray,k,context,geom,primID,a0,a1,a2,a3,Epilog(ray,k,context,geomID,primID)))
return true;
mask &= movemask(tNear <= vfloat<M>(ray.tfar[k]));
}
return false;
}
template<typename Intersector, typename Epilog>
static __forceinline void intersect_n(Precalculations& pre, RayHitK<K>& ray, const size_t k, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,k,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(normal.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
const Vec3fa ray_org(ray.org.x[k], ray.org.y[k], ray.org.z[k]);
const TensorLinearCubicBezierSurface3fa curve = geom->getNormalOrientedCurve<typename Intersector::SourceCurve3ff, typename Intersector::SourceCurve3fa, TensorLinearCubicBezierSurface3fa>(context, ray_org, primID,ray.time()[k]);
Intersector().intersect(pre,ray,k,context,geom,primID,curve,Epilog(ray,k,context,geomID,primID));
mask &= movemask(tNear <= vfloat<M>(ray.tfar[k]));
}
}
template<typename Intersector, typename Epilog>
static __forceinline bool occluded_n(Precalculations& pre, RayK<K>& ray, const size_t k, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,k,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(shadow.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
const Vec3fa ray_org(ray.org.x[k], ray.org.y[k], ray.org.z[k]);
const TensorLinearCubicBezierSurface3fa curve = geom->getNormalOrientedCurve<typename Intersector::SourceCurve3ff, typename Intersector::SourceCurve3fa, TensorLinearCubicBezierSurface3fa>(context, ray_org, primID,ray.time()[k]);
if (Intersector().intersect(pre,ray,k,context,geom,primID,curve,Epilog(ray,k,context,geomID,primID)))
return true;
mask &= movemask(tNear <= vfloat<M>(ray.tfar[k]));
}
return false;
}
template<typename Intersector, typename Epilog>
static __forceinline void intersect_h(Precalculations& pre, RayHitK<K>& ray, const size_t k, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,k,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(normal.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
Vec3ff p0,t0,p1,t1; geom->gather_hermite(p0,t0,p1,t1,geom->curve(primID),ray.time()[k]);
Intersector().intersect(pre,ray,k,context,geom,primID,p0,t0,p1,t1,Epilog(ray,k,context,geomID,primID));
mask &= movemask(tNear <= vfloat<M>(ray.tfar[k]));
}
}
template<typename Intersector, typename Epilog>
static __forceinline bool occluded_h(Precalculations& pre, RayK<K>& ray, const size_t k, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,k,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(shadow.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
Vec3ff p0,t0,p1,t1; geom->gather_hermite(p0,t0,p1,t1,geom->curve(primID),ray.time()[k]);
if (Intersector().intersect(pre,ray,k,context,geom,primID,p0,t0,p1,t1,Epilog(ray,k,context,geomID,primID)))
return true;
mask &= movemask(tNear <= vfloat<M>(ray.tfar[k]));
}
return false;
}
template<typename Intersector, typename Epilog>
static __forceinline void intersect_hn(Precalculations& pre, RayHitK<K>& ray, const size_t k, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,k,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(normal.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
const Vec3fa ray_org(ray.org.x[k], ray.org.y[k], ray.org.z[k]);
const TensorLinearCubicBezierSurface3fa curve = geom->getNormalOrientedHermiteCurve<typename Intersector::SourceCurve3ff, typename Intersector::SourceCurve3fa, TensorLinearCubicBezierSurface3fa>(context, ray_org, primID,ray.time()[k]);
Intersector().intersect(pre,ray,k,context,geom,primID,curve,Epilog(ray,k,context,geomID,primID));
mask &= movemask(tNear <= vfloat<M>(ray.tfar[k]));
}
}
template<typename Intersector, typename Epilog>
static __forceinline bool occluded_hn(Precalculations& pre, RayK<K>& ray, const size_t k, RayQueryContext* context, const Primitive& prim)
{
vfloat<M> tNear;
vbool<M> valid = intersect(ray,k,prim,tNear);
const size_t N = prim.N;
size_t mask = movemask(valid);
while (mask)
{
const size_t i = bscf(mask);
STAT3(shadow.trav_prims,1,1,1);
const unsigned int geomID = prim.geomID(N);
const unsigned int primID = prim.primID(N)[i];
const CurveGeometry* geom = context->scene->get<CurveGeometry>(geomID);
const Vec3fa ray_org(ray.org.x[k], ray.org.y[k], ray.org.z[k]);
const TensorLinearCubicBezierSurface3fa curve = geom->getNormalOrientedHermiteCurve<typename Intersector::SourceCurve3ff, typename Intersector::SourceCurve3fa, TensorLinearCubicBezierSurface3fa>(context, ray_org, primID,ray.time()[k]);
if (Intersector().intersect(pre,ray,k,context,geom,primID,curve,Epilog(ray,k,context,geomID,primID)))
return true;
mask &= movemask(tNear <= vfloat<M>(ray.tfar[k]));
}
return false;
}
};
}
}